CS227495B1 - Circuitry for generating signals modulated by frequency shift,with spectrum filtration - Google Patents

Description

The invention relates to a circuit for generating a frequency shift modulated (FSK) signal with spectrum filtering, in particular for transmitting two-state digital information.

Hitherto known frequency shift modulation circuitry consists of the actual aodulator and the transmission band-pass filters. The modulators are implemented either as LC oscillators or digital circuits based on program division of frequencies or addition of different pulse sequences with different frequencies. Transmitting band-pass filters that limit the spectrum of the transmitted signal and thus allow a frequency multiplex are usually passive IC filters.

The disadvantages of overhead circuits are low stability of LC oscillators and filters, high demands on the quality of components, difficulties in achieving symmetry and difficult automation of production of these circuits.

The purpose of the invention is to overcome these disadvantages. According to the essence of the invention, this is achieved in that the input of the binary signal is not connected to the input of a time mirror formed by both a directional counter whose first output is not connected to the input of the first modulator via the first low-pass filter. The first output of the timing circuit is connected to the control input of the first modulator e the output of the first modulator is connected to the first input of the summation circuit.

The second time mirror output is connected to the second modulator input via the second low-pass filter, its control input is connected to the second timer circuit input. The output of the second modulator is connected to the second input of the summation circuit, the output of which is the wiring output. The first output of the clock source is connected to the clock input of the time mirror. The second output of the clock source is connected to the input of a programmable divider whose output is not connected to the input of the timing circuit.

The connection according to the invention can be easily tuned only by changing the carrier frequency. The source of frequencies is simplified, producing only one frequency for each channel β one clock frequency common for all channels, which creates Czech shifted signals.

An example of a circuit for generating a frequency shift modulated signal is described in the drawing. FIG. 1 is a block diagram; FIG. 2 shows waveforms of signals.

The two-state detecting signal comes at the input 1 of the time mirror 2. The mirror mirror 6 is a bidirectional counter controlled by the input signal. The first output of the time mirror 2 is not connected to the input of the first low-pass filter 2 · Its output is connected to the input of the first modulator 2> to the output of which the first input of the summing circuit χ is connected. The second output of the time mirror 2 is connected to the input of the second low pass filter 6. The output of the second low-pass filter 6 is connected to the input of the second modulator 6, to the output of which the second input of the summation circuit X is connected.

The first source output clock signal 8 is not connected to the clock input timing mirror 2, the second source output clock frequency is unbonded no input programmable divider output 2 · 2 programmable divider d ^e unbonded to the input of the timing circuit 10. caber output timing circuit 10 is unbonded to control input of the first modulator 2> the second output is connected to the control input of the second modulator 6,

At the input 6 of the time mirror 2 is the input detecting signal 6 shown in FIG. 2. Its first output is a waveform 2, its second output is a waveform 6 having a frequency equal to half of the modulation frequency stroke and offset by a quarter of a period. The keying, i.e. the change of the input data signal at moments £ 1, £ 2, will cause the waveforms 2, s to be mirror-symmetrical with respect to the time of the keying 11, 02. Both waveforms 6, 8 are routed through identical low-pass filters 2> 1 to unbalanced modulators 2> 6. From the modulators 24, the waveforms are routed to the summation circuit χ. At the output 12 of the summation circuit X, a frequency-modulated signal with a limited spectrum is obtained.

In low pass filters 2> £ ^{36 it} removes the higher harmonic components of the rectangular waveforms as well as the transient effect caused by the keying of the input signal. By filtering the low-frequency signal in two ways, perfect arithmetic symmetry of the signal spectrum is achieved and the center-band accuracy is only dependent on the carrier frequency accuracy. Instead of a demanding bandpass filter, two low pass filters with less selectivity are used.

Ferasite modulation components can be removed by a smoothing filter with a tunable control frequency proportional to the modulation frequency. The smoothing filter is connected to the output 12 of the summation circuit X. The control input of the smoothing filter is connected to the second output of the programmable divider.

The circuit for generating a frequency shift modulated signal according to the invention is intended for data accuracy by a multiple tone telegraphy system. 1 may be used in other digital information transmission systems using a frequency modulated signal where bandwidth limitation of the transmitted signal is required.

Claims (2)

OBJECT OF THE INVENTION Wiring for generating a frequency shift modulated signal with spectrum filtering characterized in that the signal input ¢ 1) is connected to a time mirror input (2) consisting of a bi-directional counter, the first output of which is connected to the input of the first modulator (5), whose control input is connected to the first input of the summation circuit (7), the second time mirror output (2) is connected via the second low-pass filter (4) to the input of the second modulator (6) whose control input is connected the wired output of the numbering circuit (10), the output of which is connected to the second input of the summing circuit (7), the output of which (12) is the output of the wiring, the first output of the clock source (8) not being connected to and the second output of the clock source (8) is connected to the input of the programmable divider (9), the output of which is not connected to the input of the counting circuit. 2. A wavelength-modulated frequency-modulated signal generation circuit according to claim 1, characterized in that the output (12) of the summation circuit (7) is not connected to the first input of the tunable smoothing filter whose control input is not connected to the second output of the 9).